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高效石油降解菌修复石油污染土壤与强化机制分析
引用本文:姚贞先,王丽萍,李丹,李亚平,何士龙,赵雅琴. 高效石油降解菌修复石油污染土壤与强化机制分析[J]. 环境科学, 2023, 44(8): 4599-4610
作者姓名:姚贞先  王丽萍  李丹  李亚平  何士龙  赵雅琴
作者单位:中国矿业大学环境与测绘学院,徐州 221116;中国石化管道储运有限公司科技研发中心,徐州 221008
基金项目:国家自然科学基金项目(51974314, 52270171); 中国矿业大学未来科学家计划项目(2022WLJCRCZL263); 江苏省研究生科研与实践创新计划项目(SJCX22_1159)
摘    要:利用定向驯化高效石油降解菌系对石油污染土壤进行为期120 d原位修复,考察生物强化修复效果、土壤理化性质和酶活性的变化,结合宏基因组测序及生物信息学分析揭示其强化机制.结果表明,与空白对照组(Ctrl)相比,生物修复组(Exp-BT)总石油烃降解率显著提升,增幅达81.23%; 高效石油降解菌生物强化修复期间土壤pH变化稳定,体系氧化能力提高,电导率处于适宜农业活动范围内; 脂肪酶和脱氢酶在修复期间保持较高活性; 另对初始污染土壤样本(B0)、驯化所得高效石油降解菌系样本(GZ)和生物修复后土壤样本(BT)的分析显示,门水平上变形菌门与放线菌门相对丰度增加17.1%,属水平上NocardioidesAchromobacterGordoniaRhodococcus等丰度明显上升,COG和KEGG物种与功能贡献度分析证明以上菌属对石油烃降解有重要贡献; 修复后土壤中发现高丰度的石油烃相关代谢酶及5个降解基因:alkM、tamA、rubB、ladAalkB,分析表明外源石油烃降解菌群的引入增强了微生物相关酶的代谢活性与相应功能基因的表达.

关 键 词:石油污染  高效石油降解菌  强化机制  代谢途径  功能基因
收稿时间:2022-10-01
修稿时间:2022-11-02

Remediation of Petroleum-contaminated Soil by Highly Efficient Oil-degrading Bacteria and Analysis of Its Enhancement Mechanism
YAO Zhen-xian,WANG Li-ping,LI Dan,LI Ya-ping,HE Shi-long,ZHAO Ya-qin. Remediation of Petroleum-contaminated Soil by Highly Efficient Oil-degrading Bacteria and Analysis of Its Enhancement Mechanism[J]. Chinese Journal of Environmental Science, 2023, 44(8): 4599-4610
Authors:YAO Zhen-xian  WANG Li-ping  LI Dan  LI Ya-ping  HE Shi-long  ZHAO Ya-qin
Affiliation:School of Environment Science and Spatial Informatics, China University of Mining and Technology, Xuzhou 221116, China;Research and Development Center for Science & Technology, SINOPEC Pipeline Storage & Transportation Co., Ltd., Xuzhou 221008, China
Abstract:A 120-day in situ remediation of oil-contaminated soil was carried out by using highly efficient oil-degrading bacteria. The effects of bio-enhanced remediation and changes in soil physicochemical properties and enzyme activities were investigated. Combined with metagenomic sequencing and bioinformatics analysis, the strengthening mechanism was revealed. The results showed that compared with the blank control group (Ctrl), the degradation rate of total petroleum hydrocarbons in the bioremediation group (Exp-BT) was significantly increased, reaching 81.23%. During enhanced bioremediation by highly efficient oil-degrading bacteria, the pH of the soil was stable, the oxidation capacity of the system was improved, and the electrical conductivity was in the range suitable for agricultural activities. Lipase and dehydrogenase maintained high activity during repair. In addition, the analysis of the initial contaminated soil (B0), the highly efficient oil-degrading bacteria obtained from domestication (GZ), and the soil samples after bioremediation (BT) in the obtained samples showed that, at the phylum level, the total proportion of Proteobacteria and Actinobacteria increased by 17.1%. At the genus level, the abundance of Nocardioides, Achromobacter, Gordonia, and Rhodococcus increased significantly. The species and function contribution analysis of COG and KEGG proved that the above bacterial genera had important contributions to the degradation of petroleum hydrocarbons. A high abundance of petroleum hydrocarbon-related metabolic enzymes and five petroleum hydrocarbon-related degradation genes was found in the soil after remediation:alkM, tamA, rubB, ladA, and alkB. The analysis showed that the introduction of the exogenous petroleum hydrocarbon-degrading bacteria group enhanced the metabolic activity of microorganism-related enzymes and the expression of corresponding functional genes.
Keywords:oil pollution  highly efficient petroleum-degrading bacteria  strengthening mechanism  metabolic pathways  functional genes
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